Showing total 14 results

1. Study on the Operation Strategy of Ventilated Photovoltaic Windows in Hot-Summer and Cold-Winter Zone in China.

Author

Wang, Chunlei, Peng, Jinqing, Li, Nianping, Wang, Meng, and Li, Xue

Subjects

WINDOWS, VENTILATION, NUMERICAL analysis, ENERGY conservation in buildings, ENERGY consumption of buildings, AIR conditioning

Abstract

This paper investigates the overall energy performance of a ventilated amorphous silicon photovoltaic (a-Si PV) window under different operation strategies in the hot-summer and cold-winter zone. A validated numerical model based on EnergyPlus was developed and utilized to simulate the thermal, power and overall energy performance of the a-Si PV window. With the integrated numerical model, the effects of air gap depth and ventilation modes on the electricity generation, energy consumption of the air conditioning system and building net energy consumption was investigated. The results indicate that the natural ventilation mode of the ventilated a-Si PV window performs best in summer while the non-ventilation mode is the best choice in winter in the hot-summer and cold-winter zone, Changsha. With the increasing of air gap depth, the net electricity use decreases first and then increases. Based on the simulation results, the optimal structure designing and ventilation operation strategy are recommended. The findings of this paper could provide guidelines for optimizing the structure and the operation strategy of the ventilated a-Si PV windows in hot-summer and cold-winter zone in China. [ABSTRACT FROM AUTHOR]

Published

2017

2. Dynamic coupling between a Kriging-based daylight model and building energy model.

Author

Yi, Yun Kyu

Subjects

*ENERGY consumption of buildings, *DAYLIGHT, *ENERGY harvesting, *ENERGY conservation in buildings, *ALGORITHMS, *KRIGING, *COMPUTER simulation

Abstract

Harvesting daylight for improving building energy performance has become an important issue in recent years. Most energy simulation tools use a Daylight Factor (DF) based algorithm to capture the complexity of daylight behaviors. However, DF has a limitation for fully accounting realistic daylight conditions, and several modifications or integrations with other supporting tools were developed to compensate for this limitation. This paper uses the Kriging method to predict daylight conditions for a whole year, and couples this method with energy simulation tools. Kriging is a group of geo-statistical techniques used to interpolate the value of a random field at an unobserved location from discrete observed values at nearby locations. In previous research, the Kriging method showed promising outcomes; that result was significantly better than current daylight modeling in energy simulation tool, and very close to the results from advanced physics-based daylight simulation tool. However, Kriging also comes with certain limitations that require further investigation. One major hurdle was Kriging’s long computational time compared to current daylight models in energy simulation tools. For this reason, this paper aims to find possibilities to reduce computational time to realistic levels that can be applicable in practice. Furthermore, it proposes a method to integrate Kriging-based daylight model with an energy simulation tool that can plot hourly indoor light distribution. This proposal obtains more realistic results than current energy simulation daylight models, while reducing computational expense. [ABSTRACT FROM AUTHOR]

Published

2016

3. Building energy simulation in real time through an open standard interface.

Author

Pang, Xiufeng, Nouidui, Thierry S., Wetter, Michael, Fuller, Daniel, Liao, Anna, and Haves, Philip

Subjects

*ENERGY consumption of buildings, *ENERGY conservation in buildings, *COMPUTER simulation, *BUILDING design & construction, *SOFTWARE development tools

Abstract

Building energy models (BEMs) are typically used for design and code compliance for new buildings and in the renovation of existing buildings to predict energy use. The increasing adoption of BEM as standard practice in the building industry presents an opportunity to extend the use of BEMs into construction, commissioning and operation. In 2009, the authors developed a real-time simulation framework to execute an EnergyPlus model in real time to improve building operation. This paper reports an enhancement of that real-time energy simulation framework. The previous version only works with software tools that implement the custom co-simulation interface of the Building Controls Virtual Test Bed (BCVTB), such as EnergyPlus, Dymola and TRNSYS. The new version uses an open standard interface, the Functional Mockup Interface (FMI), to provide a generic interface to any application that supports the FMI protocol. In addition, the new version utilizes the Simple Measurement and Actuation Profile (sMAP) tool as the data acquisition system to acquire, store and present data. This paper introduces the updated architecture of the real-time simulation framework using FMI and presents proof-of-concept demonstration results which validate the new framework. [ABSTRACT FROM AUTHOR]

Published

2016

4. ObepME: An online building energy performance monitoring and evaluation tool to reduce energy performance gaps.

Author

Jradi, M., Arendt, K., Sangogboye, F.C., Mattera, C.G., Markoska, E., Kjærgaard, M.B., Veje, C.T., and Jørgensen, B.N.

Subjects

*ENERGY consumption of buildings, *ENERGY conservation in buildings, *ENVIRONMENTAL engineering of buildings, *BUILDING operation management, *ELECTRIC power production, *VENTILATION

Abstract

A major challenge facing the buildings sector is the absence of continuous commissioning and the lack of performance monitoring and evaluation leading to buildings energy performance gaps between predicted and actual measured performance. Aiming to better characterize, evaluate and bridge these gaps, the paper proposes an online building energy performance monitoring and evaluation tool ObepME, serving as a basis for fault detection and diagnostics and forming a backbone for continuous commissioning. A calibrated building dynamic energy model is developed and employed to automatically run on a daily basis and simulate the building transient performance for the previous day. The simulated energy consumption results form a baseline to which the actual collected data are compared to evaluate the dynamic energy performance gap. The OU44 University building in Denmark is considered as a case study to implement the proposed framework. A holistic energy model was developed in EnergyPlus and calibrated employing data from various building meters, collected weather conditions, generated occupancy schedules and systems operational parameters and set-points. The calibrated model was employed in the ObepME tool to automatically and continuously monitor and evaluate the OU44 building energy performance, on the level of the whole building and individual energy systems consumption, throughout the period from February to mid-March 2017. The reported dynamic energy performance gap was around −2.85%, −3.47% and 5.48% for heating, total electricity and ventilation system electricity consumption. In addition, specific observations were made on a daily basis in terms of the overall electricity, heating, lighting and ventilation energy consumption as highlighted by the ObepME tool. The ObepME tool is currently running automatically as a part of the OU44 building continuous commissioning and performance evaluation aiming to identify possible discrepancies and deviations paving the way for a methodical preventive fault detection and diagnostics process on various levels in the building. [ABSTRACT FROM AUTHOR]

Published

2018

5. Evaluating approaches for district-wide energy model calibration considering the Urban Heat Island effect.

Author

Santos, Luis Guilherme Resende, Afshari, Afshin, Norford, Leslie K., and Mao, Jiachen

Subjects

*URBAN heat islands, *ENERGY consumption of buildings, *ENERGY conservation in buildings, *PARAMETER estimation, *ATMOSPHERIC temperature

Abstract

Over the past decade, the building energy research community has increasingly focused on urban-scale models. The shortcomings of analyzing isolated buildings in an urban context are well-known and far from negligible, mainly due to the inability to account for Urban Heat Island (UHI), shading from neighboring obstructions, and obstructed wind flow. The aim of this paper is to evaluate the impact of the urban context via urban-scale modelling and inverse parameter estimation (calibration) using metered building energy consumption. We describe an automated calibration process for modelling 56 buildings in a representative district in downtown Abu Dhabi (UAE), where a detailed energy audit was conducted with data from 2008 to 2010. Since the urban ambient air temperature could differ significantly from the reference rural air temperature used in most building simulations, the calibration procedure will also consider this UHI effect. Two main approaches of district-wide energy model calibration are proposed using a genetic algorithm and compared to a baseline case where UHI is not considered. The first approach estimates seven building-related parameters together with four microclimate-related variables (describing annual average and seasonal variation of the UHI effect on both air temperature and humidity). The second one uses the Urban Weather Generator (UWG) to pre-process the urban EPW file, thereby reducing the number of the parameters to be estimated. In addition, two approaches are investigated for the calculation of the ASHRAE Guideline 14 calibration error metrics (CvRMSE and NMBE). One approach is to look at the whole district as one aggregate building, while the other, introduced for the first time herein, consists in deriving the weighted-average of the error of each building. The main contribution of this study is to provide simultaneous calibration for multiple buildings in the same district—and subject to the same UHI intensity. Hence, the UHI intensity (urban-rural temperature/humidity differential) is estimated alongside other calibration parameters. For the weighted average approach, CvRMSE found is between 19.09% and 19.40%, while NMBE is between 16.24% and 16.39%. For the aggregated building, CvRMSE is between 2.71% and 4.04%, while NMBE is between 1.95% and 2.35%. [ABSTRACT FROM AUTHOR]

Published

2018

6. Development and validation of a new variable refrigerant flow system model in EnergyPlus.

Author

Hong, Tianzhen, Sun, Kaiyu, Zhang, Rongpeng, Hinokuma, Ryohei, Kasahara, Shinichi, and Yura, Yoshinori

Subjects

*ENERGY consumption of buildings, *REFRIGERANTS, *THERMAL comfort, *HEAT pumps, *COMPUTER simulation, *ENERGY conservation in buildings

Abstract

Variable refrigerant flow (VRF) systems vary the refrigerant flow to meet the dynamic zone thermal loads, leading to more efficient operations than other system types. This paper introduces a new model that simulates the energy performance of VRF systems in the heat pump (HP) operation mode. Compared with the current VRF-HP models implemented in EnergyPlus, the new VRF system model has more component models based on physics and thus has significant innovations in: (1) enabling advanced controls, including variable evaporating and condensing temperatures in the indoor and outdoor units, and variable fan speeds based on the temperature and zone load in the indoor units, (2) adding a detailed refrigerant pipe heat loss calculation using refrigerant flow rate, operational conditions, pipe length, and pipe insulation materials, (3) improving accuracy of simulation especially in partial load conditions, and (4) improving the usability of the model by significantly reducing the number of user input performance curves. The VRF-HP model is implemented in EnergyPlus and validated with measured data from field tests. Results show that the new VRF-HP model provides more accurate estimate of the VRF-HP system performance, which is key to determining code compliance credits as well as utilities incentive for VRF technologies. [ABSTRACT FROM AUTHOR]

Published

2016

7. An occupant behavior modeling tool for co-simulation.

Author

Hong, Tianzhen, Sun, Hongsan, Chen, Yixing, Taylor-Lange, Sarah C., and Yan, Da

Subjects

*ENERGY consumption of buildings, *ENERGY conservation in buildings, *MATHEMATICAL models, *COMPUTER simulation, *THERMAL comfort

Abstract

Traditionally, in building energy modeling (BEM) programs, occupant behavior (OB) inputs are deterministic and less indicative of real world scenarios, contributing to discrepancies between simulated and actual energy use in buildings. This paper presents a new OB modeling tool, with an occupant behavior functional mock-up unit (obFMU) that enables co-simulation with BEM programs implementing functional mock-up interface (FMI). The components detailed in the development of the obFMU include an overview of the DNAS (drivers-needs-actions-systems) ontology and the occupant behavior eXtensible Markup Language (obXML) schema, in addition to details on the creation of the obFMU that contains the co-simulation interface, the data model and solvers. To demonstrate functionality of the tool, three examples of occupant behaviors were simulated, including: (1) turning on and off lights, (2) opening and closing windows, and (3) turning on and off the air conditioners. The obFMU can be used via co-simulation with all building simulation programs that implement the FMI, thus users are not limited to a particular tool. Another advantage is the use of obXML schema to represent occupant behavior, standardize the description of occupant behavior enabling information exchange. [ABSTRACT FROM AUTHOR]

Published

2016

8. Occupant-oriented mixed-mode EnergyPlus predictive control simulation.

Author

Zhao, Jie, Lam, Khee Poh, Ydstie, B. Erik, and Loftness, Vivian

Subjects

*ENERGY consumption of buildings, *ENERGY conservation in buildings, *PREDICTIVE control systems, *COMPUTER simulation, *HEATING, *VENTILATION, *AIR conditioning, *THERMAL comfort

Abstract

Model predictive control (MPC) has been studied in the building science realm for about three decades. However, the following two aspects of the building control have not been studied thoroughly in MPC research. One is the impact of the mixed-mode cooling system on the active heating ventilation and air conditioning (HVAC) energy consumption, and the other is the differences of individual thermal comfort preference and its impact on energy. This paper proposes an occupant-oriented mixed-mode EnergyPlus predictive control system to optimize HVAC energy consumption while meeting the individual thermal comfort preference. A web-based dashboard is implemented in the test-bed building for three months to collect individual thermal comfort preference data. The data analysis results suggest that occupants have various tolerances and preferences about thermal comfort. The simulation results show that, during one week of a typical swing season, the mixed-mode system further reduces the active HVAC energy consumption, and the diversified occupant thermal comfort preference has significant impact on HVAC energy consumption. [ABSTRACT FROM AUTHOR]

Published

2016

9. Green roofs energy performance in Mediterranean climate.

Author

Silva, Cristina M., Gomes, M. Glória, and Silva, Marcelo

Subjects

*ENERGY consumption of buildings, *HEATING, *ENERGY conservation in buildings, *GREEN roofs, *COMPUTER simulation, *THERMAL insulation

Abstract

This paper quantifies green roofs energy savings which is a challenging topic, namely in Mediterranean climate with distinct heating and cooling seasons. The thermal behavior of a green roof case study in Lisbon, Portugal, was assessed through an experimental campaign during heating and cooling periods of the year of 2013. These experimental results were then used to calibrate a building energy simulation in EnergyPlus. After validation, the numerical model was used to compare the energy performance of intensive, semi-intensive and extensive green roofs. The three green roof types lead to similar heating energy needs but extensive green roof solution shows higher cooling energy needs than semi-intensive and intensive ones, of 2.8 and 5.9 times more, respectively. Furthermore, the performance of each type of green roof and different insulation properties was compared to traditional roof solutions. With no thermal insulation, extensive green roofs require 20% less energy use than black roofs and show a similar annual behavior than white roofs. Semi-intensive and intensive green roofs energy use is 60–70% and 45–60% lower than black and white roofs, respectively. Well insulated roofs do not take full advantage of evapotranspiration cooling effects, which is particularly noticeable when comparing with high reflective white roofs. [ABSTRACT FROM AUTHOR]

Published

2016

10. Modelling and calibration of a high-mass historic building for reducing the prebound effect in energy assessment.

Author

Giuliani, Marco, Henze, Gregor P., and Florita, Anthony R.

Subjects

*HISTORIC building maintenance & repair, *MATHEMATICAL models, *ENERGY consumption of buildings, *ENERGY conservation in buildings, *THERMAL properties of buildings

Abstract

Through a case study building equipped with an advanced monitoring system, and toward the development of a general historic-building retrofit strategy, this paper presents a contribution to the calibration of building thermal models, characterized by massive and thick walls, common features of historic Italian architecture. Model calibration is performed to assess the values of parameters which are most representative of the measured building behaviour. The approach introduces sensitivity analysis for factor fixing, harnessing hourly data and metrics that take into account surface temperatures. With the measured data and simulations, the relative importance of model parameters is inferred. Different error metrics and models configuration are presented and compared in order to determine the best approach allowing the detailed calibration of building and overcoming the model limitations within EnergyPlus to characterize the heat capacity of radiators. The procedure is verified by evaluating heating energy consumption comparing different models to measured data. The resulting “prebound” effect is lowered from 64% to 3.5%. The temperature root mean square error of indoor air is lowered to below 0.5 K in both summer and winter. New error metrics increase the overall model reliability. The methodology is implemented in an open-source software tool chain that may be used in other building types. [ABSTRACT FROM AUTHOR]

Published

2016

11. Commercial Building Energy Saver: An energy retrofit analysis toolkit.

Author

Hong, Tianzhen, Piette, Mary Ann, Chen, Yixing, Lee, Sang Hoon, Taylor-Lange, Sarah C., Zhang, Rongpeng, Sun, Kaiyu, and Price, Phillip

Subjects

*ENERGY consumption of buildings, *ENERGY conservation in buildings, *RETROFITTING, *ENERGY industries, *ENERGY economics

Abstract

Small commercial buildings in the United States consume 47% of the total primary energy of the buildings sector. Retrofitting small and medium commercial buildings poses a huge challenge for owners because they usually lack the expertise and resources to identify and evaluate cost-effective energy retrofit strategies. This paper presents the Commercial Building Energy Saver (CBES), an energy retrofit analysis toolkit, which calculates the energy use of a building, identifies and evaluates retrofit measures in terms of energy savings, energy cost savings and payback. The CBES Toolkit includes a web app (APP) for end users and the CBES Application Programming Interface (API) for integrating CBES with other energy software tools. The toolkit provides a rich set of features including: (1) Energy Benchmarking providing an Energy Star score, (2) Load Shape Analysis to identify potential building operation improvements, (3) Preliminary Retrofit Analysis which uses a custom developed pre-simulated database and, (4) Detailed Retrofit Analysis which utilizes real-time EnergyPlus simulations. CBES includes 100 configurable energy conservation measures (ECMs) that encompass IAQ, technical performance and cost data, for assessing 7 different prototype buildings in 16 climate zones in California and 6 vintages. A case study of a small office building demonstrates the use of the toolkit for retrofit analysis. The development of CBES provides a new contribution to the field by providing a straightforward and uncomplicated decision making process for small and medium business owners, leveraging different levels of assessment dependent upon user background, preference and data availability. [ABSTRACT FROM AUTHOR]

Published

2015

12. Optimization of thermal insulation of a house heated by using radiant panels.

Author

Cvetković, Dragan and Bojić, Milorad

Subjects

*ENERGY consumption of buildings, *FLOOR heating systems, *THERMAL insulation, *ENERGY conservation in buildings, *RADIANT heating

Abstract

Radiant panels are known to be energy efficient sensible heating systems and a suitable fit for low-energy buildings. The main goal of this paper is to optimize the thermal insulation layers of house heated by using the radiant heating systems. This work is conducted to study four radiant systems: floor-heating system, wall-heating system, ceiling-heating system and newly developed floor-ceiling heating system located in a net-zero-energy house in Kragujevac, Serbia. The operation of these panels is simulated by software EnergyPlus. For the optimization of the optimal length of the thermal insulation software GenOpt is used. [ABSTRACT FROM AUTHOR]

Published

2014

13. Performances of low temperature radiant heating systems.

Author

Bojić, Milorad, Cvetković, Dragan, Marjanović, Vesna, Blagojević, Mirko, and Djordjević, Zorica

Subjects

*ENVIRONMENTAL engineering of buildings, *RADIANT heating, *FLOORS, *ENERGY consumption of buildings, *ENERGY conservation in buildings, *BUILDING performance, *CEILINGS, *CARBON dioxide mitigation

Abstract

Abstract: This paper reports investigations of energy, environmental, and economic performances of floor, wall, ceiling, and floor–ceiling heating. It is found that the floor–ceiling heating has the best performances: the lowest energy and exergy consumption, exergy destruction, CO2 emissions (compound, direct, and avoidable), and operation costs. In addition, it uses boiler of the lowest power. The worst system by all these parameters is the classical ceiling heating. The comparison of the room operative air temperatures and the operative air temperatures set by thermostats shows that all systems give satisfactory results without significant deviations. The largest deviation and the lowest values of the surrounding inner surfaces of the exterior walls are found for the floor–ceiling ceiling panel system. [Copyright &y& Elsevier]

Published

2013

14. Evaluation of weather datasets for building energy simulation

Author

Bhandari, Mahabir, Shrestha, Som, and New, Joshua

Subjects

*ENERGY consumption of buildings, *COMMERCIAL buildings, *DWELLINGS, *ENERGY conservation in buildings, *CALIBRATION, *MICROCLIMATOLOGY, *SOLAR radiation, *SIMULATION methods & models

Abstract

Abstract: In recent years, calibrated energy modeling of residential and commercial buildings has gained importance in a retrofit-dominated market. Accurate weather data play an important role in this calibration process and projected energy savings. It would be ideal to measure weather data at the building location to capture relevant microclimate variation but this is generally considered cost-prohibitive. There are data sources publicly available with high temporal sampling rates but at relatively poor geospatial sampling locations. To overcome this limitation, there are a growing number of service providers that claim to provide real time and historical weather data necessary for building modeling at 15–40km2 grid across the globe; common variables such as temperature and precipitation have been constructed on ∼1km2 grids . Unfortunately, there is limited documentation from 3rd-party sources attesting to the accuracy of this data. This paper compares provided weather characteristics with data collected from a weather station inaccessible to the service providers. Monthly average dry bulb temperature; relative humidity; direct normal, diffuse and global solar radiation; wind speed and wind direction are statistically compared. Moreover, we ascertain the relative contribution of each weather variable and its impact on building loads. Annual simulations are performed for three different building types, including a closely monitored and automated energy efficient research building. The comparison shows that the difference for an individual variable can be as high as 90%. In addition, annual building energy consumption can vary by ±7% while monthly building loads can vary by ±40% as a function of the provided location''s weather data. [Copyright &y& Elsevier]

Published

2012